JP6565016B2 - Aging prediction apparatus and program - Google Patents

Description

  The present invention relates to an aging prediction apparatus and a program.

There are various techniques for estimating the age of a person from the skin, body shape, face, etc.
In Patent Document 1, as a related technique, a technique for obtaining a proportion age based on a trunk fat mass and a lower limb fat mass is described.

Japanese Patent Laid-Open No. 2004-081621

By the way, this proportion age is an index expressing the current appearance from the viewpoint of the body type.
However, for such an index, the demand for estimating the future is higher than the current situation.

  Therefore, the present invention aims to solve the conventional problems as described above, and an object thereof is to provide an aging prediction apparatus and program capable of easily predicting aging.

In order to solve the above problems, the aging prediction apparatus of the present invention is
An anti-aging index estimating means for estimating an anti-aging index based on a body fat percentage index and a muscle development index;
Based on the anti-aging index estimated by the anti-aging index estimation means, an aging rate estimation means for estimating an aging rate;
It is characterized by providing.

In addition, the aging prediction apparatus of the present invention,
The anti-aging index estimation means is
Based on the body fat percentage index and the mean and standard deviation of the same sex, as the anti-aging index, a first individual anti-aging index estimation means for estimating an anti-aging index based on a body fat percentage index;
Based on the muscle development degree index and the mean and standard deviation of the same sex, as the anti-aging index, a second individual anti-aging index estimation means for estimating an anti-aging index by a muscle development degree index,
An anti-aging index based on the body fat percentage index estimated by the first individual anti-aging index estimation means, and an anti-aging index based on the muscle development degree index estimated by the second individual anti-aging index estimation means And having a comprehensive anti-aging index estimating means for estimating a comprehensive anti-aging index,
It is characterized by that.

In addition, the aging prediction apparatus of the present invention,
The anti-aging index estimation means is
Based on the body fat percentage index and the mean and standard deviation of the same sex, as the anti-aging index, a first individual anti-aging index estimation means for estimating an anti-aging index based on a body fat percentage index;
Based on the anti-aging index by the body fat percentage index estimated by the first individual anti-aging index estimation means, and having a comprehensive anti-aging index estimation means for estimating a total anti-aging index,
It is characterized by that.

In addition, the aging prediction apparatus of the present invention,
The anti-aging index estimation means is
Based on the muscle development degree index and the mean and standard deviation of the same sex, as the anti-aging index, a second individual anti-aging index estimation means for estimating an anti-aging index by a muscle development degree index,
Based on the anti-aging index by the muscle development degree index estimated by the second individual anti-aging index estimation means, and having a comprehensive anti-aging index estimation means for estimating a total anti-aging index,
It is characterized by that.

In addition, the aging prediction apparatus of the present invention,
A current visual age estimation means for estimating the current visual age,
A forecast timing acquisition means for acquiring a forecast timing;
Based on the current appearance age estimated by the current appearance age estimation means, the prediction time acquired by the prediction time acquisition means, and the aging speed estimated by the aging speed estimation means, a future appearance age A future appearance age estimation means for estimating
Is further provided.

In addition, the aging prediction apparatus of the present invention,
Real age acquisition means for acquiring real age;
Comparing the current appearance age estimated by the current appearance age estimation means with the actual age acquired by the actual age acquisition means, and determining the current appearance age state;
The future appearance age state determination means for comparing the future appearance age estimated by the future appearance age estimation means and the actual age acquired by the actual age acquisition means, and determining the state of the future appearance age;
Appearance age for comprehensively determining the appearance age based on the current appearance age state determined by the current appearance age state determination means and the future appearance age state determined by the future appearance age state determination means Comprehensive judgment means;
Is further provided.

In addition, the aging prediction apparatus of the present invention,
A body fat percentage index estimating means for estimating the body fat percentage index;
Muscle development index estimation means for estimating the muscle development index;
Is further provided.

The program of the present invention is
Computer
An anti-aging index estimating means for estimating an anti-aging index based on a body fat percentage index and a muscle development index;
Aging rate estimation means for estimating the aging rate based on the anti-aging index estimated by the anti-aging index estimation means,
To function as.

The program of the present invention is
The computer,
The anti-aging index estimation means is
Based on the body fat percentage index and the mean and standard deviation of the same sex, as the anti-aging index, a first individual anti-aging index estimation means for estimating an anti-aging index based on a body fat percentage index,
A second individual anti-aging index estimating means for estimating an anti-aging index based on a muscle development index as the anti-aging index based on the muscle development index and the mean and standard deviation of the same sex;
An anti-aging index based on the body fat percentage index estimated by the first individual anti-aging index estimation means, and an anti-aging index based on the muscle development degree index estimated by the second individual anti-aging index estimation means Based on the above, a comprehensive anti-aging index estimation means for estimating a comprehensive anti-aging index,
To function as.

  According to the aging prediction apparatus of the present invention, aging can be easily predicted.

It is a figure which shows the correlation with glycoalbumin and a body fat percentage parameter | index. It is a figure which shows correlation with a somatomedin and a muscle development level parameter | index. It is an external view which shows the external appearance of the aging prediction apparatus concerning this invention. It is a block diagram which shows the structure of the aging prediction apparatus concerning this invention. It is a flowchart of the process (until the present appearance is determined) by the measurement program of the aging prediction apparatus concerning this invention. It is a flowchart of the process (until the future appearance is determined) by the measurement program of the aging prediction apparatus according to the present invention. It is a data table which shows the statistical result of a body fat percentage index. It is a data table which shows the statistical result of a muscular development index. It is a data table for calculating | requiring a comprehensive anti-aging parameter | index. It is a data table for comprehensive determination. It is a graph which shows the relationship between the future appearance age and the present appearance age. It is a graph which shows the relationship between the future appearance age and the present appearance age in the case where it looks older than actual age now. It is a graph which shows the relationship between the future appearance age in the case where it looks younger than real age now, and the present appearance age. It is a data table for calculating | requiring a comprehensive anti-aging parameter | index. (Modification) It is a data table for calculating | requiring a comprehensive anti-aging parameter | index. (Modification)

  (A) It is generally known that when an excess sugar is formed in the body, it binds to the protein, the protein is denatured, and the denatured protein generates an aging substance, but this is closely related to the excess sugar at this time. Glycoalbumin used as a blood glucose level index correlates with the body fat percentage index as shown in the relationship between the body fat percentage index and glycoalbumin in FIG. 1, and (b) depending on the secretion of growth hormone The present inventors have found that somatomedin (IFG-I), which is produced and inhibits cellular senescence, correlates with muscle development index as shown in the relationship between muscle development index and somatomedin in FIG. It was done.

  Here, the body fat percentage index is the body fat percentage, or a factor (for example, the length (weight) of the body (whole body or part)), weight, bioimpedance (reactance component or resistance component). ), Etc., obtained from two or more of the above). In addition, the muscle development degree index is a muscle development degree or an element that greatly contributes to this (for example, a value obtained from a reactance component of bioimpedance and a resistance component of bioimpedance, bioimpedance and low frequency in high frequency measurement) The values obtained from the bioimpedance in the measurement, the values obtained from the resistance component of the bioimpedance in the high frequency measurement, and the resistance component of the bioimpedance in the low frequency measurement, etc.) are shown.

  Accordingly, the present inventor has created the following aging prediction apparatus according to the present invention in order to achieve the object by focusing on these points.

<Example>
First, a specific configuration of the aging prediction apparatus according to the present invention will be described with reference to FIGS. 3 and 4.

  FIG. 3 is an external view of an aging prediction apparatus according to the present invention. As shown in FIG. 3, the aging prediction apparatus 1 has a configuration in which a grip portion 121 is detachably set on a main body 120. The main body 120 and the grip part 121 are connected by a communication cable (not shown). The communication cable is accommodated in the main body 120 in a state where a force for pulling back the main body 120 is applied. For this reason, when the person to be measured places his / her body on the main body 120, grasps the grip portion 121 with both hands, removes it from the main body 120, and takes a standing posture, the communication cable is pulled out from the main body 120. When the measurement is finished and the grip 121 is returned to the main body 120, the communication cable is pulled back to the main body 120 and automatically accommodated in the main body 120.

  The main body 120 includes a first foot energizing electrode 106a for the left foot toe side, a second foot energizing electrode 106b for the right foot toe side, a first foot measuring electrode 105a for the left foot side, and a right foot side. The second foot measurement electrode 105b is provided.

  The first foot energizing electrode 106a is formed at a position where the toe side of the left foot contacts when the left foot is placed on the main body 120, and the second foot energizing electrode 106b is formed when the right foot is placed on the main body 120. It is formed in the position where the toe side contacts.

  The first foot measurement electrode 105a is formed at a position where the heel side of the left foot contacts when the left foot is placed on the main body 120, and the second foot measurement electrode 105b is formed when the right foot is placed on the main body 120. It is formed in the position where the heel side contacts.

  The gripper 121 includes a first hand energizing electrode 106c for the left hand finger side, a second hand energizing electrode 106d for the right hand finger side, a first hand measuring electrode 105c for the left hand palm side, A second hand measurement electrode 105d for the palm side of the right hand, a display unit 110, and an input unit 111 are provided.

  The first hand energizing electrode 106c is formed at a position where the finger side of the left hand contacts when the left side of the grasping part 121 is grasped with the left hand, and the second hand energizing electrode 106d is formed with the right hand on the right side of the grasping part 121. It is formed at a position where the finger side of the right hand contacts when gripped.

  The first hand measurement electrode 105c is formed at a position where the palm side of the left hand contacts when the left side of the grip part 121 is gripped by the left hand, and the second hand measurement electrode 105d is formed by the right hand of the grip part 121. It is formed at a position where the palm side of the right hand contacts when grasped.

  FIG. 4 is a block diagram of an aging prediction apparatus according to the present invention. As shown in FIG. 4, the aging prediction apparatus 1 includes a power supply unit 101, a weight measurement unit 102, a weight sensor 103, a bioelectrical impedance measurement unit 104, a measurement electrode 105 (first foot measurement electrode 105a, second foot measurement). Electrode 105b, first hand measuring electrode 105c, second hand measuring electrode 105d), energizing electrode 106 (first foot energizing electrode 106a, second foot energizing electrode 106b, first hand energizing electrode 106c, first A two-handed electrode 106d), a first switching unit 107a, a second switching unit 107b, a timing unit 109, a display unit 110, an input unit 111, a storage unit 112, a communication unit 113, and a calculation / control unit 114.

  The power supply unit 101 supplies power to each part of the electrical system of this apparatus.

  The weight sensor 103 detects the weight acting on the main body and outputs a weight signal.

  The weight measuring unit 102 converts the weight signal output from the weight sensor 103 into a weight signal for calculating body weight.

  The first switching unit 107 a switches to the measurement electrode 105 connected to the bioimpedance measurement unit 104 under the control of the calculation / control unit 114. Here, the measurement electrode 105 is selected from the first foot measurement electrode 105a, the second foot measurement electrode 105b, the first hand measurement electrode 105c, and the second hand measurement electrode 105d according to the body measurement site. What you need is selected.

  The second switching unit 107 b switches to the energization electrode 106 connected to the bioimpedance measurement unit 104 under the control of the calculation / control unit 114. Here, the energizing electrode 106 is selected from the first foot energizing electrode 106a, the second foot energizing electrode 106b, the first hand energizing electrode 106c, and the second hand energizing electrode 106d in accordance with the energized part of the body. What you need is selected.

The bioelectrical impedance measurement unit 104 causes an AC constant current to flow through the body through the energization electrode 106 switched by the second switching unit 107b under the control of the calculation / control unit 114, and the measurement impedance switched by the first switching unit 107a. The voltage generated in the body through the electrode 105 is measured.
Here, the AC constant current is supplied for each of a reference frequency (for example, 50 kHz), a high frequency (for example, 250 kHz), and a low frequency (for example, 5 kHz), and the voltage for each is measured. .

  The timer 109 measures time.

  The input unit 111 acquires body specifying information such as age, gender, and height, prediction time, and other input information input according to a user's operation under the control of the calculation / control unit 114.

  The display unit 110 is controlled based on the operation information necessary for executing the measurement program by the calculation / control unit 114, the input information acquired by the input unit 111, and the weight measurement unit 102 under the control of the calculation / control unit 114. The measured result information, the result information measured based on the bioelectrical impedance measuring unit, various result information obtained by the calculation / control unit 114, and other notification information are displayed.

  The storage unit 112 stores in advance a measurement program executed by the calculation / control unit 114 and the following various arithmetic expressions and data tables used in the execution of the measurement program. Further, input information acquired by the input unit 111, result information obtained by execution of the measurement program by the calculation / control unit 114, and other various information are stored.

Note that the following various arithmetic expressions and data tables are obtained by analyzing an unspecified number of subjects as a sample by a statistical method or the like.
A. Various arithmetic expressions a. Calculation formulas by gender for obtaining trunk fat mass, lower extremity fat mass, body fat percentage and other body composition indices, for example, trunk fat mass = f (bioimpedance, body weight, height), lower extremity fat mass = f (Bioimpedance, weight, height), body fat percentage = f (bioimpedance, weight, height),
b. Calculation formula for each gender for obtaining the current appearance age, for example, the current appearance age = trunk fat amount / lower extremity fat amount,
c. Calculation formula for gender for obtaining body fat percentage index: For example, body fat percentage index = coefficient × (height ² ÷ body weight ÷ bioimpedance),
d. Male / female calculation formulas for obtaining muscle development index: For example, muscle development index = bioimpedance by high frequency measurement ÷ bioimpedance by low frequency measurement,
e. Calculation formula for each gender for obtaining an anti-aging index based on a body fat percentage index: For example, an anti-aging index based on a body fat percentage index = (body fat percentage index−average value) ÷ standard deviation value,
f. Calculation formula for each gender for obtaining an anti-aging index based on a muscle development index: For example, an anti-aging index based on a muscle development index = (muscle development index−average value) ÷ standard deviation value,
g. Calculation formula for gender for obtaining aging rate: For example, aging rate = 1 + total anti-aging index ÷ 3,
h. Formula for calculating the future appearance age, for example: Future appearance age = current appearance age + aging rate × predicted time,
B. Various data tables i. Data table showing statistical results of body fat percentage index, for example, FIG.
j. Data table showing statistical results of muscle development index, for example, FIG.
k. Gender-specific data table for obtaining a general anti-aging index, for example, FIG. 9, FIG. 14, FIG.
m. Data table for comprehensive determination ... For example, FIG.

Here, in the gender-specific data table for obtaining the total anti-aging index shown in FIG. 9, a1 to g7 in the column indicating the total anti-aging index are a1 → a7 → g7 and a1 → g1 → g7. It shows a lower value, and further shows the slope of a straight line in the relationship graph between the future appearance age and the current appearance age shown in FIG. Is set to a value such that
Further, in the data table for each gender for obtaining the overall anti-aging index shown in FIG. 14, h1 to h7 in the column showing the overall anti-aging index become lower as h1 → h7, and further, the aging rate is obtained. Thus, a value is set that indicates the slope of a straight line in the relationship graph between the future apparent age and the current apparent age shown in FIG.
Further, in the data table for each gender for obtaining the general anti-aging index shown in FIG. 15, i1 to i7 in the column indicating the general anti-aging index become lower as i1 → i7, and further, the aging rate is obtained. Thus, a value is set that indicates the slope of a straight line in the relationship graph between the future apparent age and the current apparent age shown in FIG.

  The communication unit 113 transmits / receives input information, result information, and other communication information to / from a mobile terminal such as a smartphone, a tablet terminal, and a mobile phone, a personal computer, a biometric device, and other external devices by wireless communication or wired communication.

  The calculation / control unit 114 controls each unit constituting the apparatus, and executes a process of FIG. 3 described later based on a measurement program stored in the storage unit 112 in advance.

In addition, various means are comprised by the combination of each part mentioned above.
(I) Body fat percentage for estimating a body fat percentage index by a storage section 112 that stores a measurement program and a gender-specific computation formula for obtaining a body fat percentage index in advance and a calculation / control section 114 that executes the measurement program An index estimation unit is configured.
(Ii) Muscle development degree for estimating a muscle development degree index by a storage unit 112 for storing a measurement program and a male / female calculation formula for obtaining a muscle development degree index in advance and a calculation / control unit 114 for executing the measurement program An index estimation unit is configured.
(Iii) Measurement program, data table showing statistical results of body fat percentage index, and storage unit 112 for preliminarily storing gender-specific arithmetic expressions for obtaining anti-aging indices based on body fat percentage indices, and computation for executing the measurement program -The control part 114 comprises the 1st separate anti-aging index estimation means which estimates the anti-aging index by a body fat percentage index.
(Iv) A measurement program, a data table indicating statistical results of muscle development index, and a storage unit 112 for storing an arithmetic expression for each gender for obtaining an anti-aging index based on the muscle development index, and an operation for executing the measurement program -The control part 114 comprises the 2nd separate anti-aging index estimation means which estimates the anti-aging index by a muscle development degree index.
(V) A total that estimates a total anti-aging index by a storage unit 112 that stores in advance a gender-specific data table for obtaining a measurement program and a total anti-aging index and a calculation / control unit 114 that executes the measurement program Configure anti-aging index estimation means.
(Vi) The first individual anti-aging index estimation means, the second individual anti-aging index estimation means and the total anti-aging index estimation means, or the first individual anti-aging index estimation means and the total resistance Anti-aging index estimation means for estimating an anti-aging index is constituted by the aging index estimation means or by the second individual anti-aging index estimation means and the total anti-aging index estimation means.
(Vii) The aging rate estimation means for estimating the aging rate is configured by the storage unit 112 that stores the measurement program and the gender-specific calculation formula for obtaining the aging rate in advance and the calculation / control unit 114 that executes the measurement program.
(Viii) Current appearance age for estimating the current appearance age by the storage unit 112 that stores the measurement program and the gender-specific calculation formula for obtaining the current appearance age in advance and the calculation / control unit 114 that executes the measurement program The estimation means is configured.
(Ix) A prediction time acquisition unit that acquires a prediction time is configured by the input unit that acquires the prediction time, the storage unit 112 that stores the measurement program in advance, and the calculation / control unit 114 that executes the measurement program. .
(X) Future appearance age estimation means for estimating a future appearance age by a storage unit 112 that stores a measurement program and an arithmetic expression for obtaining a future appearance age in advance and an operation / control unit 114 that executes the measurement program Configure.
(Xi) The input part which acquires age, the memory | storage part 112 which memorize | stores a measurement program previously, and the calculating / control part 114 which performs a measurement program comprise the real age acquisition means which acquires real age.
(Xii) The storage unit 112 that stores the measurement program in advance and the calculation / control unit 114 that executes the measurement program constitute a current appearance age state determination unit that determines the state of the current appearance age.
(Xiii) The storage unit 112 that stores the measurement program in advance and the calculation / control unit 114 that executes the measurement program constitute a future appearance age state determination unit that determines the state of the future appearance age.
(Xiv) A visual age comprehensive determination means for performing a comprehensive determination on the visual age by the storage unit 112 that stores a measurement program and a data table for comprehensive determination in advance, and the calculation / control unit 114 that executes the measurement program Configure.

  In addition, a computer is configured by the storage unit 112 that stores various arithmetic expressions, data tables, and measurement programs in advance, and the calculation / control unit 114 that executes the measurement program.

Next, the processing of the measurement program executed in the calculation / control unit 114 of the aging prediction apparatus 1 according to the present invention will be described mainly using FIGS. 5 and 6.
The calculation / control unit 114 causes the storage unit 112 to store each piece of result information obtained in the execution stage of the measurement program process.
FIG. 5 is a flowchart of processing until the current appearance is determined by the measurement program of the aging prediction apparatus according to the present invention.

  In step S <b> 1, when the user inputs body specifying information such as age, gender, and height from the input unit 111 and a predicted time, the input unit specific information and the predicted time are stored in the storage unit 112. .

  In step S <b> 2, when the measurement subject holds the grip unit 121 with both hands and is placed on the main body 120 in a standing posture, the weight sensor 103 and the weight measurement unit 102 output the weight for calculation. The body weight is obtained from the weight signal.

In step S3, as will be described in detail below, the required measurement electrode 105 is switched using the first switching unit 107a according to the body part to be measured, while the required energization electrode 106 is switched to the second. Switching is performed using the switching unit 107b, and the bioelectrical impedance for each of the whole body and each body part is obtained from the AC constant current supplied from the bioelectrical impedance measuring unit 104 and the measured voltage.
Here, the bioelectrical impedance for each of the whole body and each body part is obtained when an alternating constant current having a reference frequency (for example, 50 kHz) is applied, and an alternating constant current having a high frequency (for example, 250 kHz) is applied. It is obtained for each of when a low frequency (for example, 5 kHz) AC constant current is passed.

In particular,
(1) When measuring the bioelectrical impedance of the whole body, the second switching unit 107b is used to select and switch between the first foot energizing electrode 106a and the first hand energizing electrode 106c, while the first switching unit 107a. Is used to select and switch between the first foot measurement electrode 105a and the first hand measurement electrode 105c, and the bioelectrical impedance of the whole body is obtained from the AC constant current flowed from the bioimpedance measurement unit 104 and the measured voltage.
(2) When measuring the bioimpedance between both hands, the first switching unit 106b is used to select and switch between the first hand-carrying electrode 106c and the second hand-carrying electrode 106d, while the first switching unit The first hand measurement electrode 105c and the second hand measurement electrode 105d are selected and switched using 107a, and the bioimpedance between both hands is obtained from the AC constant current supplied from the bioimpedance measurement unit 104 and the measured voltage.
(3) When measuring the bioimpedance of the right arm, the second switching unit 107b is used to select and switch between the second hand energizing electrode 106d and the second foot energizing electrode 106b, while the first switching unit 107a. The first hand measurement electrode 105c and the second hand measurement electrode 105d are selected and switched, and the bioimpedance of the right arm is obtained from the AC constant current supplied from the bioimpedance measurement unit 104 and the measured voltage.
(4) When measuring the bioimpedance of the left arm, the second switching unit 107b is used to select and switch between the first hand energizing electrode 106c and the first foot energizing electrode 106a, while the first switching unit 107a. The first hand measurement electrode 105c and the second hand measurement electrode 105d are selected and switched, and the bioimpedance of the left arm is obtained from the AC constant current passed from the bioimpedance measurement unit 104 and the measured voltage.
(5) When measuring the bioimpedance of the right leg, the second switching unit 107b is used to select and switch the second hand energizing electrode 106d and the second foot energizing electrode 106b, while the first switching The first foot measurement electrode 105a and the second foot measurement electrode 105b are selected and switched using the unit 107a, and the bioelectrical impedance of the right leg is obtained from the AC constant current passed from the bioimpedance measurement unit 104 and the measured voltage. .
(6) When measuring the bioelectrical impedance of the left leg, the first switching unit 106b is used to select and switch between the first hand energizing electrode 106c and the first foot energizing electrode 106a, while the first switching unit The first foot measurement electrode 105a and the second foot measurement electrode 105b are selected and switched using 107a, and the bioelectrical impedance of the left leg is obtained from the AC constant current supplied from the bioimpedance measurement unit 104 and the measured voltage.
(7) When measuring the bioimpedance between both feet, the first switching unit 107b is used to select and switch between the first foot energizing electrode 106a and the second foot energizing electrode 106b, while the first switching unit The first foot measurement electrode 105a and the second foot measurement electrode 105b are selected and switched using 107a, and the bioimpedance between both feet is obtained from the AC constant current passed from the bioimpedance measurement unit 104 and the measured voltage.
(8) When measuring the bioelectrical impedance of the trunk, the first switching unit 106b is used to select and switch between the first hand-carrying electrode 106c and the first foot-carrying electrode 106a, while the first switching unit The second hand measurement electrode 105d and the second foot measurement electrode 105b are selected and switched using the 107a, and the bioimpedance of the trunk is obtained from the AC constant current supplied from the bioimpedance measurement unit 104 and the measured voltage.

  In step S4, it is determined whether the sex stored in the storage unit 112 is female or male.

In step S5, the calculated bioimpedance and body weight of the trunk are input to the gender-specific arithmetic expression (which corresponds to the gender determined in step S4) for obtaining the trunk fat mass stored in advance in the storage unit 112. Substituting the height of the body to determine the fat mass of the trunk.
Next, the gender-specific calculation formula (which corresponds to the gender determined in step S4) for calculating the lower extremity fat amount stored in advance in the storage unit, the calculated bioimpedance and weight between both feet, and the input height Substituting for the lower extremity fat mass.
Then, the calculated trunk fat mass and lower extremity fat mass are substituted into the gender-specific calculation formula (the one corresponding to the gender determined in step S4) for obtaining the current appearance age stored in advance in the storage unit. Find the age of appearance.

  In step S6, the obtained current apparent age is compared with the input age (actual age).

  In step S7, after step S6, when the current appearance age is higher than the actual age in the comparison result, the current appearance age state is determined as “currently looks old”.

  In step S8, after step S6, when the current appearance age is lower than the actual age in the comparison result, the current appearance age state is determined as “currently looks young”.

  In step S9, after step S6, when the current apparent age is the same as the actual age in the comparison result, it is determined that the current apparent age is “currently suitable for age”.

  FIG. 6 is a flowchart of processing until the future appearance is determined by the measurement program of the aging prediction apparatus 1 according to the present invention.

In step S10, the bioimpedance between both feet based on the obtained reference frequency measurement and the gender-specific calculation formula (corresponding to the gender determined in step S4) for obtaining the body fat percentage index stored in advance in the storage unit 112, and The body fat percentage index is obtained by substituting the body weight and the input height.
Next, the bioelectrical impedance and low frequency between both feet by the high frequency measurement obtained in the gender-specific arithmetic expression (which corresponds to the gender determined in step S4) for obtaining the muscle development degree index stored in advance in the storage unit 112 The muscle development index is obtained by substituting the bioimpedance between both feet from the measurement.

In step S11, the calculated body fat percentage index and the gender-specific arithmetic expression for calculating the anti-aging index based on the body fat percentage index stored in advance in the storage unit 112 (corresponding to the gender determined in step S4) According to the body fat percentage index by substituting the average value and standard deviation value (corresponding to the same gender acquired in step S1) in the data table showing the statistical result of the body fat percentage index stored in advance in the storage unit Find anti-aging indicators.
Next, the calculated muscle development index and the storage unit in the calculation formula for each gender for determining the anti-aging index based on the muscle development index stored in advance in the storage unit (corresponding to the gender determined in step S4) Substituting the mean value and standard deviation value (corresponding to the same gender acquired in step S1) in the data table showing the statistical result of the muscle development degree index stored in advance into the anti-aging by the muscle development degree index Find the indicator.

  In step S12, the body fat percentage index obtained based on the gender-specific data table (corresponding to the gender determined in step S4) for obtaining the total anti-aging index shown in FIG. The total anti-aging index corresponding to the anti-aging index by the muscle and the anti-aging index by the muscle development index is specified.

  In step S13, the aging rate is obtained by substituting the specified comprehensive anti-aging index into the gender-specific calculation formula (which corresponds to the sex determined in step S4) for obtaining the aging rate stored in advance in the storage unit. .

  In step S14, a future appearance age is obtained by substituting the calculated aging rate and the current appearance age and the input prediction time into an arithmetic expression for obtaining a future appearance age stored in advance in the storage unit. Ask for.

  In step S15, the determined future apparent age is compared with the input age (actual age).

  In step S <b> 16, after step S <b> 15, if the future appearance age is higher than the actual age in the comparison result, the state of the future appearance age is determined as “looks old in the future”.

  In step S <b> 17, after step S <b> 15, when the future appearance age is lower than the actual age in the comparison result, the state of the future appearance age is determined as “looks young in the future”.

  In step S18, after step S15, if the future appearance age is the same as the actual age in the comparison result, it is determined that the future appearance age state is “looks like the age in the future”.

  In step S19, following step S16, step S17, or step S18, based on the data table for comprehensive determination stored in advance in the storage unit, the comprehensive determination corresponding to the current appearance age and the future appearance age that have been obtained. The result is specified, and the specified comprehensive determination result is displayed on the display unit 110 or output by the communication unit 113.

  Thus, the processing of the measurement program executed in the calculation / control unit 114 is completed.

  Here, the relationship between the current appearance age obtained in step S5 described above, the aging rate obtained in step S13, and the future appearance age (appearance age after the predicted years) obtained in step S14 is shown in FIGS. It will be described in the following.

  FIG. 11 shows a case where the current appearance age and the future appearance age are the same when the current appearance age is the horizontal axis and the future appearance age is the vertical axis, that is, the aging speed S = 1 (that is, the aging speed is appropriate). For example, after 5 years, the current appearance age is the same as the future appearance age, and when the future appearance age is lower than the current appearance age, the aging rate S <1 (that is, the aging rate is low, for example, 5 years later, if the future appearance age is 3 years lower than the current appearance age, and the future appearance age is higher than the current appearance age, then the aging rate S> 1 (ie, the aging rate is 5 years Then, the future appearance age is 2 years higher than the current appearance age).

  FIG. 12 is a graph showing an actual age lower than the current apparent age on the horizontal axis of the graph showing the relationship of FIG. For example, at aging rate S <1, the current apparent age is currently higher than the actual age, but after 5 years, the future apparent age will be lower. At aging rate S> 1, the actual age is currently lower than the actual age. Although the present age of appearance is high, it indicates that the age of appearance in the future will be further increased after 5 years.

  FIG. 13 is a graph showing the actual age higher than the current apparent age on the horizontal axis of the graph showing the relationship of FIG. For example, the current appearance age is currently lower than the actual age at an aging rate S <1, but the future appearance age will be further lowered after 5 years. The present age at an aging rate S> 1 Although the current appearance age is lower than 5 years, the future appearance age will increase after 5 years.

  As described above, according to the aging prediction apparatus described above, estimation is performed by the aging rate estimation means based on the body fat percentage index estimated by the body fat percentage index estimation means and the muscle development degree index estimated by the muscle development degree index estimation means. The aging rate can be estimated by the future appearance age estimation means and the future appearance age can be estimated by the future appearance age state determination means to obtain the future appearance age state. Can be predicted.

<Modification>
In the embodiment described above, in step S10, a body fat percentage index and a muscle development degree index are obtained, and in step S11, an anti-aging index based on the body fat percentage index and an anti-aging index based on the muscle development degree index are obtained, In step S12, an overall anti-aging index corresponding to the anti-aging index based on the body fat percentage index and the anti-aging index based on the muscle development degree index is specified. In step S13, the aging rate is determined based on the total anti-aging index. Seeking. That is, when determining the aging rate, it is performed based on the body fat percentage index and the muscle development degree index, but can be similarly performed even if it is performed based on either the body fat percentage index or the muscle development degree index.

In particular,
In step S10, the bioimpedance between both feet by the obtained reference frequency measurement and the gender-specific calculation formula (corresponding to the gender determined in step S4) for obtaining the body fat percentage index stored in advance in the storage unit 112, and The body fat percentage index is obtained by substituting the body weight and the input height. Or the bioimpedance and low frequency between both feet by the obtained high frequency measurement in the gender-specific calculation formula (corresponding to the gender determined in step S4) for obtaining the muscle development degree index stored in advance in the storage unit 112 The muscle development index is obtained by substituting the bioimpedance between both feet from the measurement.
Next, in step S11, the calculated body fat percentage is calculated according to the gender-specific calculation formula (corresponding to the gender determined in step S4) for obtaining the anti-aging index based on the body fat percentage index stored in advance in the storage unit 112. The body fat percentage by substituting the index and the average value and standard deviation value (corresponding to the same gender acquired in step S1) in the data table indicating the statistical result of the body fat percentage index stored in advance in the storage unit Find anti-aging index by index. Alternatively, the calculated muscle development index and the storage unit in the gender-specific arithmetic expression for calculating the anti-aging index based on the muscle development index stored in advance in the storage unit (corresponding to the gender determined in step S4) Substituting the mean value and standard deviation value (corresponding to the same gender acquired in step S1) in the data table showing the statistical result of the muscle development degree index stored in advance into the anti-aging by the muscle development degree index Find the indicator.
Next, in step S12, the body fat determined based on the gender-specific data table (corresponding to the gender determined in step S4) for determining the total anti-aging index shown in FIG. The total anti-aging index corresponding to the anti-aging index by the rate index is specified. Or, based on the gender-specific data table (corresponding to the gender determined in step S4) for obtaining the total anti-aging index shown in FIG. Identify the overall anti-aging index that corresponds to the aging index.
Next, in step S13, the calculation formula for each gender for determining the aging rate stored in advance in the storage unit (corresponding to the gender determined in step S4) corresponds to the anti-aging index by the specified body fat percentage index Substitute the total anti-aging index to find the aging rate. Alternatively, the aging rate is obtained by substituting a comprehensive anti-aging index corresponding to the anti-aging index based on the specified muscle development degree index.

  As described above, the aging rate can be obtained even if it is performed based on either the body fat percentage index or the muscle development degree index.

  In the above-described embodiment, various arithmetic expressions and data tables are stored in the storage unit 112 in advance. However, the arithmetic expressions are in the form of data tables, and the data tables are in the same way in the arithmetic expressions. Can be implemented.

  Further, in the above-described embodiment, the result body shape of the current appearance age state determined in step S7 to step S9, and the body shape according to the result of the future appearance age state determined in step S16 to step S18. It is also possible to display on the display unit 110.

In the above-described embodiments, specific arithmetic expressions are exemplified as various arithmetic expressions stored in advance in the storage unit 112, but the present invention is not limited to this.
For example, instead of “height” in the illustrated calculation formula “coefficient × (height ² ÷ weight ÷ bioimpedance)” as a calculation formula for gender for obtaining a body fat percentage index, “leg length” Instead of “body weight”, “lower limb weight” may be used, or “biological impedance” instead of “biological impedance”. Further, the “bioimpedance” may be “bioimpedance between both feet” or “bipodal impedance of one leg”.
In addition, instead of the illustrated calculation formula “muscle development index = bioimpedance by high-frequency measurement ÷ bioimpedance by low-frequency measurement” as an arithmetic expression for each gender for obtaining the muscle development index, “muscle development index = biological impedance” “Reactance component of impedance ÷ resistance component of bioimpedance” or “muscle development degree index = resistance component of bioimpedance by high frequency measurement ÷ resistance component of bioimpedance by low frequency measurement”.
Alternatively, “muscle development level index = bioimpedance by first frequency measurement ÷ bioimpedance by second frequency measurement” (however, the first frequency and the second frequency are different). In this case, an AC constant current of a first frequency (for example, 250 kHz) and a second frequency (for example, 200 kHz) is supplied from the bioimpedance measurement unit 104, and the voltage for each is measured.
In the calculation / control unit 114, the parameters in the calculation formula to be used are obtained based on various information obtained from the input unit 111, the weight measurement unit 102, and the bioimpedance measurement unit 104, and are similarly substituted by using the calculation formula to be used. It can be implemented.

In the above-described embodiment, the measurement program is stored in advance in the storage unit 112 and executed by the calculation / control unit 114. However, the measurement program is a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, The present invention can be implemented even if it is stored in a recording medium such as a semiconductor memory and executed by the calculation / control unit 114.
In addition, the measurement program is stored in a mobile terminal such as a smartphone, a tablet terminal, or a mobile phone, a personal computer, a biometric device, or other external device, and is executed by the external device or the calculation / control unit 114. Is possible.
Further, the measurement program can be implemented even if it is downloaded through a website and executed by an external device or the calculation / control unit 114.

DESCRIPTION OF SYMBOLS 1 ... Aging prediction apparatus 101 ... Power supply part 102 ... Weight measuring part 103 ... Weight sensor 104 ... Bioimpedance measuring part 105a ... First foot measuring electrode 105b ... Second Foot measuring electrode 105c ... first hand measuring electrode 105d ... second hand measuring electrode 106a ... first foot energizing electrode 106b ... second foot energizing electrode 106c ... first Electrode 106d for manual energization ... Second electrode for manual energization 107a ... First switching unit 107b ... Second switching unit 109 ... Timing unit 110 ... Display unit 111 ... Input unit 112- ..Storage unit 113 ... Communication unit 114 ... Calculation / control unit 120 ... Main body 121 ... Gripping unit

Claims (9)

An anti-aging index estimating means for estimating an anti-aging index based on a body fat percentage index and a muscle development index;
Based on the anti-aging index estimated by the anti-aging index estimation means, an aging rate estimation means for estimating an aging rate;
An aging prediction apparatus comprising: The anti-aging index estimation means is
Based on the body fat percentage index and the mean and standard deviation of the same sex, as the anti-aging index, a first individual anti-aging index estimation means for estimating an anti-aging index based on a body fat percentage index;
Based on the muscle development degree index and the mean and standard deviation of the same sex, as the anti-aging index, a second individual anti-aging index estimation means for estimating an anti-aging index by a muscle development degree index,
An anti-aging index based on the body fat percentage index estimated by the first individual anti-aging index estimation means, and an anti-aging index based on the muscle development degree index estimated by the second individual anti-aging index estimation means And having a comprehensive anti-aging index estimating means for estimating a comprehensive anti-aging index,
The aging prediction apparatus according to claim 1. The anti-aging index estimation means is
Based on the body fat percentage index and the mean and standard deviation of the same sex, as the anti-aging index, a first individual anti-aging index estimation means for estimating an anti-aging index based on a body fat percentage index;
Based on the anti-aging index by the body fat percentage index estimated by the first individual anti-aging index estimation means, and having a comprehensive anti-aging index estimation means for estimating a total anti-aging index,
The aging prediction apparatus according to claim 1. The anti-aging index estimation means is
Based on the muscle development degree index and the mean and standard deviation of the same sex, as the anti-aging index, a second individual anti-aging index estimation means for estimating an anti-aging index by a muscle development degree index,
Based on the anti-aging index by the muscle development degree index estimated by the second individual anti-aging index estimation means, and having a comprehensive anti-aging index estimation means for estimating a total anti-aging index,
The aging prediction apparatus according to claim 1. A current visual age estimation means for estimating the current visual age,
A forecast timing acquisition means for acquiring a forecast timing;
Based on the current appearance age estimated by the current appearance age estimation means, the prediction time acquired by the prediction time acquisition means, and the aging speed estimated by the aging speed estimation means, a future appearance age A future appearance age estimation means for estimating
The aging prediction apparatus according to any one of claims 1 to 4, further comprising: Real age acquisition means for acquiring real age;
Comparing the current appearance age estimated by the current appearance age estimation means with the actual age acquired by the actual age acquisition means, and determining the current appearance age state;
The future appearance age state determination means for comparing the future appearance age estimated by the future appearance age estimation means and the actual age acquired by the actual age acquisition means, and determining the state of the future appearance age;
Appearance age for comprehensively determining the appearance age based on the current appearance age state determined by the current appearance age state determination means and the future appearance age state determined by the future appearance age state determination means Comprehensive judgment means;
The aging prediction apparatus according to claim 5, further comprising: A body fat percentage index estimating means for estimating the body fat percentage index;
Muscle development index estimation means for estimating the muscle development index;
The aging prediction apparatus according to claim 1, further comprising: Computer
An anti-aging index estimating means for estimating an anti-aging index based on a body fat percentage index and a muscle development index;
Aging rate estimation means for estimating the aging rate based on the anti-aging index estimated by the anti-aging index estimation means,
Program to function as. The computer,
The anti-aging index estimation means is
Based on the body fat percentage index and the mean and standard deviation of the same sex, as the anti-aging index, a first individual anti-aging index estimation means for estimating an anti-aging index based on a body fat percentage index,
A second individual anti-aging index estimating means for estimating an anti-aging index based on a muscle development index as the anti-aging index based on the muscle development index and the mean and standard deviation of the same sex;
An anti-aging index based on the body fat percentage index estimated by the first individual anti-aging index estimation means, and an anti-aging index based on the muscle development degree index estimated by the second individual anti-aging index estimation means Based on the above, a comprehensive anti-aging index estimation means for estimating a comprehensive anti-aging index,
9. The program according to claim 8, wherein the program is made to function as:

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